Intelligent orchestration of video or image mirroring using a platform framework

ABSTRACT

Embodiments of systems and methods for methods for the intelligent orchestration of video or image mirroring using a platform framework are described. In some embodiments, an Information Handling System (IHS) may include a processor and a memory coupled to the processor, the memory having program instructions stored thereon that, upon execution, cause the IHS to: receive a notification, via a platform framework, of a communication session; and in response to the notification, apply a video or image mirroring operation, via the platform framework, to at least a portion of content shared during the communication session.

FIELD

The present disclosure relates generally to Information Handling Systems(IHSs), and more particularly, to systems and methods for theintelligent orchestration of video or image mirroring using a platformframework.

BACKGROUND

As the value and use of information continue to increase, individualsand businesses seek additional ways to process and store it. One optionavailable to users is Information Handling Systems (IHSs). An IHSgenerally processes, compiles, stores, and/or communicates informationor data for business, personal, or other purposes thereby allowing usersto take advantage of the value of the information. Because technologyand information handling needs and requirements vary between differentusers or applications, IHSs may also vary regarding what information ishandled, how the information is handled, how much information isprocessed, stored, or communicated, and how quickly and efficiently theinformation may be processed, stored, or communicated.

Variations in IHSs allow for IHSs to be general or configured for aspecific user or specific use such as financial transaction processing,airline reservations, enterprise data storage, or global communications.In addition, IHSs may include a variety of hardware and softwarecomponents that may be configured to process, store, and communicateinformation and may include one or more computer systems, data storagesystems, and networking systems.

SUMMARY

Embodiments of systems and methods for the intelligent orchestration ofdigital watermarking using a platform framework are described. In anillustrative, non-limiting embodiment, an Information Handling System(IHS) may include a processor and a memory coupled to the processor, thememory having program instructions stored thereon that, upon execution,cause the IHS to: receive a notification, via a platform framework, of acommunication session; and in response to the notification, apply avideo or image mirroring operation, via the platform framework, to atleast a portion of content shared during the communication session.

The communication session may include at least one of: a videocommunication, a broadcast, a virtual conference, or a remote meeting.The content may include at least one of: a live video feed, a recordedvideo, a virtual background, a watermark, a shared desktop, a sharedapplication window, or a shared document. To apply the video or imagemirroring operation, the program instructions, upon execution, may causethe IHS to apply a left-to-right or a right-to-left flip to the portionof the content.

In some cases, to apply the video or image mirroring operation, theprogram instructions, upon execution, may cause the IHS to determinewhether to enforce a video or image mirroring policy based, at least inpart, upon context. The context may include at least one of: aclassification of the content, an identity or role of an originator ofthe content, a type of the communication session, an identification orproximity of a participant of the communication session, an IHSlocation, an IHS posture, a determination of whether a camera source isfront-facing or rear-facing with respect to the IHS, or anidentification of a communication application configured to establishthe communication session.

The notification may be provided by a communication applicationregistered with the platform framework via an Application ProgrammingInterface (API), and application of the video or image mirroringoperation may be initiated by an optimizer application registered withthe platform framework via the API.

In another illustrative non-limiting embodiment, a memory storage devicemay have program instructions stored thereon that, upon execution by anIHS, cause the IHS to: identify a video or image mirroring policy; andenforce the video or image mirroring policy, via a platform framework,during a communication session.

To enforce the video or image mirroring policy, the programinstructions, upon execution, may cause the IHS to apply a left-to-rightor a right-to-left operation to content shared during the communicationsession based on context. The context may include at least one of: aclassification of the content, an identity or role of an originator ofthe content, a type of the communication session, an identification of aparticipant of the communication session, a proximity of the participantto the IHS, an IHS location, an IHS posture, a determination of whethera camera source is front-facing or rear-facing with respect to the IHS,or an identification of a communication application configured toestablish the communication session.

In yet another illustrative, non-limiting embodiment, a method mayinclude identifying a video or image mirroring policy applicable to acommunication session; and enforcing the video or image mirroring policywith respect to content shared during the communication session.Enforcing the video or image mirroring policy may include selectingbetween a left-to-right or a right-to-left operation to at least aportion of the content based on context. The context may include atleast one of: a classification of the content, an identity or role of anoriginator of the content, a type of the communication session, anidentification of a participant of the communication session, aproximity of the participant, a location, a posture, a determination ofwhether a camera source is front-facing or rear-facing, or anidentification of a communication application configured to establishthe communication session.

BRIEF DESCRIPTION OF THE DRAWINGS

The present invention(s) is/are illustrated by way of example and is/arenot limited by the accompanying figures, in which like referencesindicate similar elements. Elements in the figures are illustrated forsimplicity and clarity, and have not necessarily been drawn to scale.

FIG. 1 is a block diagram of an example of hardware components of anInformation Handling System (IHS), according to some embodiments.

FIG. 2 is a block diagram illustrating an example of a platformframework deployed in an IHS, according to some embodiments.

FIG. 3 is a message diagram illustrating an example of a method forplatform framework arbitration, according to some embodiments.

FIG. 4 is a message diagram illustrating an example of a method forplatform framework multicasting, according to some embodiments.

FIG. 5 is a block diagram illustrating an example of a system forintelligent orchestration of video participants in a platform framework,according to some embodiments.

FIG. 6 is a block diagram illustrating an example of a method forintelligent orchestration of video participants in a platform framework,according to some embodiments.

FIG. 7 is a block diagram illustrating an example screenshot ofwatermarks introduced into a communication or collaboration session by awatermarking service using intelligent orchestration of videoparticipants in a platform framework, according to some embodiments.

FIG. 8 is a block diagram illustrating an example of a watermarkingmethod executed by a watermarking service using intelligentorchestration of video participants in a platform framework, accordingto some embodiments.

FIGS. 9A and 9B are screenshots of examples of shared content subject tovideo or image mirroring, according to some embodiments.

FIG. 10 is a flowchart illustrating an example of a method forintelligent orchestration of video or image mirroring using a platformframework, according to some embodiments.

FIG. 11 is a diagram of an example of a system for eye contactcorrection in a communication or collaboration session using a platformframework, according to some embodiments.

FIG. 12 is a flowchart of an example of a method for eye contactcorrection in a communication or collaboration session using a platformframework, according to some embodiments.

DETAILED DESCRIPTION

In this disclosure, an Information Handling System (IHS) may include anyinstrumentality or aggregate of instrumentalities operable to compute,calculate, determine, classify, process, transmit, receive, retrieve,originate, switch, store, display, communicate, manifest, detect,record, reproduce, handle, or utilize any form of information,intelligence, or data for business, scientific, control, or otherpurposes. For example, an IHS may be a personal computer (e.g., desktopor laptop), tablet computer, mobile device (e.g., Personal DigitalAssistant (PDA) or smart phone), server (e.g., blade server or rackserver), a network storage device, or any other suitable device and mayvary in size, shape, performance, functionality, and price.

An IHS may include Random Access Memory (RAM), one or more processingresources such as a Central Processing Unit (CPU) or hardware orsoftware control logic, Read-Only Memory (ROM), and/or other types ofnonvolatile memory. Additional components of an IHS may include one ormore disk drives, one or more network ports for communicating withexternal devices as well as various I/O devices, such as a keyboard, amouse, touchscreen, and/or a video display. An IHS may also include oneor more buses operable to transmit communications between the varioushardware components.

FIG. 1 is a block diagram illustrating components of IHS 100 configuredaccording to some embodiments. As shown, IHS 100 includes one or moreprocessor(s) 101, such as a Central Processing Unit (CPU), that executecode retrieved from system memory 105.

Although IHS 100 is illustrated with a single processor, otherembodiments may include two or more processors, that may each beconfigured identically, or to provide specialized processing operations.Processor(s) 101 may include any processor capable of executinginstructions, such as an Intel Pentium™ series processor or anygeneral-purpose or embedded processors implementing any of a variety ofInstruction Set Architectures (ISAs), such as the x86, POWERPC®, ARM®,SPARC®, or MIPS® ISAs, or any other suitable ISA.

In the embodiment of FIG. 1 , processor(s) 101 includes integratedmemory controller 118 that may be implemented directly within itscircuitry. Alternatively, memory controller 118 may be a separateintegrated circuit that is located on the same die as processor(s) 101.Memory controller 118 may be configured to manage the transfer of datato and from system memory 105 of IHS 100 via high-speed memory interface104.

System memory 105 is coupled to processor(s) 101 and providesprocessor(s) 101 with a high-speed memory that may be used in theexecution of computer program instructions. For example, system memory105 may include memory components, such as static RAM (SRAM), dynamicRAM (DRAM), NAND Flash memory, suitable for supporting high-speed memoryoperations by the processor 101. In certain embodiments, system memory105 may combine both persistent, non-volatile, and volatile memor(ies).In certain embodiments, system memory 105 may include multiple removablememory modules.

IHS 100 utilizes chipset 103 that may include one or more integratedcircuits coupled to processor(s) 101. In this embodiment, processor(s)101 is depicted as a component of chipset 103. In other embodiments, allof chipset 103, or portions of chipset 103 may be implemented directlywithin the integrated circuitry of processor(s) 101. Chipset 103provides processor(s) 101 with access to a variety of resourcesaccessible via bus 102.

In IHS 100, bus 102 is illustrated as a single element. However, otherembodiments may utilize any number of separate buses to provide theillustrated pathways served by bus 102.

In various embodiments, IHS 100 may include one or more I/O ports 116that may support removeable couplings with various types of externaldevices and systems, including removeable couplings with peripheraldevices that may be configured for operation by a particular user of IHS100. For instance, I/O 116 ports may include USB (Universal Serial Bus)ports, by which a variety of external devices may be coupled to IHS 100.In addition to, or instead of USB ports, I/O ports 116 may includevarious types of physical I/O ports that are accessible to a user via anenclosure or chassis of IHS 100.

In certain embodiments, chipset 103 may additionally utilize one or moreI/O controllers 110 that may each support the operation of hardwarecomponents such as user I/O devices 111. User I/O devices 111 mayinclude peripheral components that are physically coupled to I/O port116 and/or peripheral components wirelessly coupled to IHS 100 vianetwork interface 109.

In various implementations, I/O controller 110 may support the operationof one or more user I/O devices 110 such as a keyboard, mouse, touchpad,touchscreen, microphone, speakers, camera and other input and outputdevices that may be coupled to IHS 100. User I/O devices 111 mayinterface with an I/O controller 110 through wired or wireless couplingssupported by IHS 100. In some cases, I/O controllers 110 may supportconfigurable operation of supported peripheral devices, such as user I/Odevices 111.

As illustrated, a variety of additional resources may be coupled toprocessor(s) 101 of IHS 100 through chipset 103. For instance, chipset103 may be coupled to network interface 109 to enable different types ofnetwork connectivity. IHS 100 may also include one or more NetworkInterface Controllers (NICs) 122 and 123, each of which may implementthe hardware required for communicating via a specific networkingtechnology, such as Wi-Fi, BLUETOOTH, Ethernet and mobile cellularnetworks (e.g., CDMA, TDMA, LTE).

Network interface 109 may support network connections by wired networkcontroller(s) 122 and wireless network controller(s) 123. Each networkcontroller 122 and 123 may be coupled via various buses to chipset 103to support different types of network connectivity, such as the networkconnectivity utilized by IHS 100.

Chipset 103 may also provide access to one or more display device(s) 108and/or 113 via graphics processor(s) 107. Graphics processor(s) 107 maybe included within a video card, graphics card, and/or an embeddedcontroller installed within IHS 100. Additionally, or alternatively,graphics processor(s) 107 may be integrated within processor(s) 101,such as a component of a system-on-chip (SoC). Graphics processor(s) 107may generate display information and provide the generated informationto display device(s) 108 and/or 113.

One or more display devices 108 and/or 113 are coupled to IHS 100 andmay utilize LCD, LED, OLED, or other display technologies (e.g.,flexible displays, etc.). Each display device 108 and 113 may be capableof receiving touch inputs such as via a touch controller that may be anembedded component of the display device 108 and/or 113 or graphicsprocessor(s) 107, for example, or may be a separate component of IHS 100accessed via bus 102. In some cases, power to graphics processor(s) 107,integrated display device 108 and/or external display 133 may be turnedoff or configured to operate at minimal power levels in response to IHS100 entering a low-power state (e.g., standby).

As illustrated, IHS 100 may support integrated display device 108, suchas a display integrated into a laptop, tablet, 2-in-1 convertibledevice, or mobile device. IHS 100 may also support use of one or moreexternal displays 113, such as external monitors that may be coupled toIHS 100 via various types of couplings, such as by connecting a cablefrom the external display 113 to external I/O port 116 of the IHS 100,via wireless docking station, etc. In certain scenarios, the operationof integrated displays 108 and external displays 113 may be configuredfor a particular user. For instance, a particular user may preferspecific brightness settings that may vary the display brightness basedon time of day and ambient lighting conditions.

Chipset 103 also provides processor(s) 101 with access to one or morestorage devices 119. In various embodiments, storage device 119 may beintegral to IHS 100 or may be external to IHS 100. Moreover, storagedevice 119 may be accessed via a storage controller that may be anintegrated component of the storage device.

Generally, storage device 119 may be implemented using any memorytechnology allowing IHS 100 to store and retrieve data. For instance,storage device 119 may be a magnetic hard disk storage drive or asolid-state storage drive. In certain embodiments, storage device 119may be a system of storage devices, such as a cloud system or enterprisedata management system that is accessible via network interface 109.

As illustrated, IHS 100 also includes Basic Input/Output System (BIOS)117 that may be stored in a non-volatile memory accessible by chipset103 via bus 102. Upon powering or restarting IHS 100, processor(s) 101may utilize BIOS 117 instructions to initialize and test hardwarecomponents coupled to the IHS 100. Under execution, BIOS 117instructions may facilitate the loading of an operating system (OS)(e.g., WINDOWS, MACOS, iOS, ANDROID, LINUX, etc.) for use by IHS 100.

BIOS 117 provides an abstraction layer that allows the operating systemto interface with the hardware components of the IHS 100. The UnifiedExtensible Firmware Interface (UEFI) was designed as a successor toBIOS. As a result, many modern IHSs utilize UEFI in addition to orinstead of a BIOS. As used herein, BIOS is intended to also encompassUEFI.

As illustrated, certain IHS 100 embodiments may utilize sensor hub 114(e.g., INTEL Sensor Hub or “ISH,” etc.) capable of sampling and/orcollecting data from a variety of hardware sensors 112. For instance,sensors 112, may be disposed within IHS 100, and/or display 110, and/ora hinge coupling a display portion to a keyboard portion of IHS 100, andmay include, but are not limited to: electric, magnetic, hall effect,radio, optical, infrared, thermal, force, pressure, touch, acoustic,ultrasonic, proximity, position, location, angle (e.g., hinge angle),deformation, bending (e.g., of a flexible display), orientation,movement, velocity, rotation, acceleration, bag state (in or out of abag), and/or lid sensor(s) (open or closed).

In some cases, one or more sensors 112 may be part of a keyboard orother input device. Processor(s) 101 may be configured to processinformation received from sensors 112 through sensor hub 114, and toperform methods for prioritizing the pre-loading of applications with aconstrained memory budget using contextual information obtained fromsensors 112.

For instance, during operation of IHS 100, the user may open, close,flip, swivel, or rotate display 108 to produce different IHS postures.In some cases, processor(s) 101 may be configured to determine a currentposture of IHS 100 using sensors 112 (e.g., a lid sensor, a hingesensor, etc.). For example, in a dual-display IHS implementation, when afirst display 108 (in a first IHS portion) is folded against a seconddisplay 108 (in a second IHS portion) so that the two displays havetheir backs against each other, IHS 100 may be said to have assumed abook posture. Other postures may include a table posture, a displayposture, a laptop posture, a stand posture, or a tent posture, dependingupon whether IHS 100 is stationary, moving, horizontal, resting at adifferent angle, and/or its orientation (landscape vs. portrait).

For instance, in a laptop posture, a first display surface of a display108 may be facing the user at an obtuse angle with respect to a seconddisplay surface of a display 108 or a physical keyboard portion. In atablet posture, a first display surface may be at a straight angle withrespect to a second display surface or a physical keyboard portion. And,in a book posture, a first display surface may have its back (e.g.,chassis) resting against the back of a second display surface or aphysical keyboard portion.

It should be noted that the aforementioned postures and their variousrespective keyboard states are described for sake of illustration only.In different embodiments, other postures may be used, for example,depending upon the type of hinge coupling the displays, the number ofdisplays used, or other accessories.

In other cases, processor(s) 101 may process user presence data receivedby sensors 112 and may determine, for example, whether an IHS's end-useris present or absent. Moreover, in situations where the end-user ispresent before IHS 100, processor(s) 101 may further determine adistance of the end-user from IHS 100 continuously or at pre-determinedtime intervals. The detected or calculated distances may be used byprocessor(s) 101 to classify the user as being in the IHS's near-field(user's position<threshold distance A), mid-field (threshold distanceA<user's position<threshold distance B, where B>A), or far-field (user'sposition>threshold distance C, where C>B) with respect to IHS 100 and/ordisplay 108.

More generally, in various implementations, processor(s) 101 may receiveand/or produce context information using sensors 112 via sensor hub 114,including one or more of, for example: a user's presence or proximitystate (e.g., present, near-field, mid-field, far-field, and/or absentusing a Time-of-Flight or “ToF” sensor, visual image sensor, infraredsensor, and/or other suitable sensor 112), a facial expression of theuser (e.g., usable for mood or intent classification), a direction andfocus of the user's gaze, a user's hand gesture, a user's voice, an IHSlocation (e.g., based on the location of a wireless access point orGlobal Positioning System, etc.), IHS movement (e.g., from anaccelerometer or gyroscopic sensor), lid state (e.g., of a laptop orother hinged form factor), hinge angle (e.g., in degrees), IHS posture(e.g., laptop, tablet, book, tent, display, etc.), whether the IHS iscoupled to a dock or docking station (e.g., wired or wireless), adistance between the user and at least one of: the IHS, the keyboard, ora display coupled to the IHS, a type of keyboard (e.g., a physicalkeyboard integrated into IHS 100, a physical keyboard external to IHS100, or an on-screen keyboard), whether the user operating the keyboardis typing with one or two hands (e.g., by determine whether or not theuser is holding a stylus, or the like), a time of day, softwareapplication(s) under execution in focus for receiving keyboard input,whether IHS 100 is inside or outside of a carrying bag or case, a levelof ambient lighting, a battery charge level, whether IHS 100 isoperating from battery power or is plugged into an AC power source(e.g., whether the IHS is operating in AC-only mode, DC-only mode, orAC+DC mode), a power mode or rate of power consumption of variouscomponents of IHS 100 (e.g., CPU 101, GPU 107, system memory 105, etc.),etc.

In certain embodiments, sensor hub 114 may be an independentmicrocontroller or other logic unit that is coupled to the motherboardof IHS 100. Sensor hub 114 may be a component of an integratedsystem-on-chip incorporated into processor(s) 101, and it maycommunicate with chipset 103 via a bus connection such as anInter-Integrated Circuit (I²C) bus or other suitable type of busconnection. Sensor hub 114 may also utilize an I²C bus for communicatingwith various sensors supported by IHS 100.

As illustrated, IHS 100 may utilize embedded controller (EC) 120, whichmay be a motherboard component of IHS 100 and may include one or morelogic units. In certain embodiments, EC 120 may operate from a separatepower plane from the main/host processor(s) 101 and thus the OSoperations of IHS 100. Firmware instructions utilized by EC 120 may beused to operate a secure execution system that may include operationsfor providing various core functions of IHS 100, such as powermanagement, management of operating modes in which IHS 100 may bephysically configured and support for certain integrated I/O functions.In some embodiments, EC 120 and sensor hub 114 may communicate via anout-of-band signaling pathway or bus 124.

In various embodiments, chipset 103 may provide processor 101 withaccess to hardware accelerator(s) 125. Examples of hardwareaccelerator(s) 125 may include, but are not limited to, INTEL's GaussianNeural Accelerator (GNA), Audio and Contextual Engine (ACE), VisionProcessing Unit (VPU), Deep Neural Network (DNN), etc. In some cases,hardware accelerator(s) 125 may be used to perform ML and/or AIoperations offloaded by processor 101. For instance, hardwareaccelerator(s) 125 may load several audio signatures and/or settings,and it may identify an audio source by comparing an audio input to oneor more audio signatures until it finds a match. Hardware accelerator(s)125 may also apply one or more video processing operations to a videoinput or workload, for example, by instantiating aspects of, orexecuting commands from, a media foundation engine, a communication orcollaboration application, or the like.

In some cases, however, hardware accelerator(s) 125 may have significantmodel concurrency and/or processing latency constraints relative toprocessor(s) 101. Accordingly, in some cases, context information may beused to select a subset and/or size of data signatures (e.g., audio),also number and/or complexity of models, number of concurrent models(e.g., only two or three models can be processed at a time), and/orlatency characteristics (e.g., with four models or more, detectionlatency becomes unacceptable) of hardware accelerator(s) 125.

In various embodiments, IHS 100 may not include each of the componentsshown in FIG. 1 . Moreover, IHS 100 may include various other componentsin addition to those that are shown in FIG. 1 . Some components that arerepresented as separate components in FIG. 1 may be integrated withother components. For example, in some implementations, all or a portionof the features provided by the illustrated components may instead beprovided by an SoC.

In a conventional IHS, each application would have to know how tocommunicate with each specific hardware endpoint 101-124 it needs, whichcan place a heavy burden on software developers. Moreover, in manysituations, multiple applications may request the same information fromthe same hardware endpoint, thus resulting in inefficiencies due toparallel and/or overlapping code and execution paths used by theseapplications to perform get and set methods with that same endpoint.

To address these, and other concerns, a platform framework as describedherein may enable an overall, comprehensive system managementorchestration of IHS 100. Particularly, such a platform framework mayprovide, among other features, the scalability of multiple applicationsrequesting direct hardware endpoint (e.g., 101-124) access.Additionally, or alternatively, a platform framework as described hereinmay provide performance optimizations and increased operationalstability to various IHS environments.

FIG. 2 is a block diagram illustrating an example of platform framework200. In some embodiments, IHS 100 may instantiate each element ofplatform framework 200 through the execution of program instructions,stored in a memory (e.g., system memory 105, storage device(s) 119,etc.), by one or more processors or controllers (e.g., processor(s) 101,GPU 107, hardware accelerators, etc.).

In some implementations, platform framework 200 may be supported byand/or executed within an OS used by IHS 100, and it may be scaledacross user and kernel spaces. Additionally, or alternatively, platformframework 200 may be provided as a software library or an “.exe” file.

As shown, platform framework 200 includes core framework backbone 201and Application Programming Interface (API) 205. Core framework backbone201 includes management and oversight engine 202 (with services 215A-N),framework telemetry database 203, and session storage database 204.

In operation, platform framework 200 enables the management andorchestration of its participants' communications. The term“participant,” as used herein, refers to any entity (e.g., hardwaredevice driver, software module, etc.) configured to register withplatform framework 200 by issuing a registration command to managementand oversight engine 202 via API 205. Upon registration, eachparticipant may receive a handle usable by services 215A-N withinmanagement and oversight engine 202 (and other participants) to addressit. In some cases, the handle may be validated by Root-of-Trust (RoT)hardware (e.g., EC 120) as part of the participant registration process.

In various embodiments, platform framework 200 may include at leastthree different types of participants: producers, consumers, andproviders.

Producers are entities (e.g., 207A-N) configured to advertise or publishthe capabilities (e.g., variables, primitives, etc.) and statuses ofassociated hardware (e.g., 206A) or software components (e.g., 206N) toplatform framework 200 via API 205, which can then be consumed and/ormodified by other participants (e.g., 210A-N). Producers (e.g., 207A-N)may also execute operations with respect to associated hardwarecomponents (e.g., 206A-N) based upon instructions (e.g., “set” commands)received from other participants (e.g., 210A-N) via API 205.

On the producer side, resources 206A-N may include, for example,hardware 206A, BIOS 206B, OS 206C, application 206D (a producer role forconsumer application 210N), and application 206N (a producer-onlyapplication). Each of resources 206A-N may have a producer driver ormodule 207A-N (a “producer”) associated therewith, and each suchproducer 207A-N may have corresponding orchestrator logic 208A-N thatenables its registration and subsequent communications with platformframework 200 via API 205. Once registered, producers 207A-N may provideinformation to platform framework 200 on their own, upon request bymanagement and oversight engine 202, and/or upon request by any consumer(e.g., 210A-N).

Consumers are entities (e.g., 210A-N) that retrieve data (e.g., a singledata item, a collection of data items, data subscribed to from selectedproducers, etc.) from platform framework 200 using API 205 to thenperform one or more actions.

On the consumer side, each of consuming applications 210A-N (a“consumer”) may have a corresponding orchestrator logic 211A-N that alsoenables registration and subsequent communications with platformframework 200 using API 205. For example, applications 210A-N may useAPI 205 commands request data via platform framework 200 from anyregistered producer 207A-N or provider 209A-N. In the case ofapplication 212 that is not natively aware of, or compliant with,platform framework 200 (e.g., the application uses direct-to-driveraccess), interface application or plugin 213 and orchestrator logic 214may enable its inter-operation with platform framework 200 via API 205.

In various embodiments, orchestrator logic 208A-N, 211A-N, and 214 areeach a set of APIs to manage a respective entity, such as applications211A-N, participants 207A-N, and PF interface 213. Particularly, eachentity may use its orchestrator interface to register themselves againstplatform framework 200, with a list of methods exposed within theorchestrator logic's APIs to query for capabilities, events tolisten/respond on, and other orchestration operations tied to routingand efficiency.

In some cases, a single application may operate both as a consumer and aproducer with respect to platform framework 200. For example,application 210N may operate as a consumer to receive BIOS data fromBIOS 206B via API 205. In response to receiving data from producer 207Bassociated with BIOS 206B, application 210N may execute one of morerules to change the IHS 100′s thermal settings. As such, the sameapplication 210N may also operate as producer 206D, for example, byregistering and/or advertising its thermal settings to platformframework 200 for consumption by other participants (e.g., 210A) via API205.

Providers 209A-N are runtime objects that collect data from multipleparticipants and make intelligent modifications to that data fordelivery to other participants (e.g., consumers) through platformframework 200. Despite a provider (e.g., 209A) being an entity withinmanagement and oversight engine 202, it may be registered and/oradvertised with platform framework 200 as if it were one of producers207A-N.

As an example, a status provider (e.g., 209A) may collect hardwareinformation from hardware resource(s) 206A and BIOS information (e.g.,from BIOS 206B), make a status determination for IHS 100 based upon thatdata, and deliver the status to platform framework 200 as if it were ahardware component or driver. As another example, a status provider(e.g., 209A) may receive user presence information from sensor hub 114(e.g., hardware 206A), receive human interface device (HID) readingsfrom OS 209C, make its user own presence determination based upon someconcatenation of those two inputs, and publish its user presencedetermination to platform framework 200 such that other participants donot have to make redundant findings.

API 205 may include a set of commands commonly required of everyparticipant (consumers and producers) of platform framework 200, forexample, to perform get or set operations or methods. Predominantly,producers 207A-N may use API 205 to register, advertise, and providedata to consumers (e.g., 210A-N), whereas consumers 210A-N may use API205 to receive that data and to send commands to producers 207A-N.

Moreover, applications 210A-N may discover all other participants (e.g.,hardware 206A and enumerated/supported capabilities, etc.) that areregistered into platform framework 200 using API 205. For example, ifhardware 206A includes graphics subsystem 107, application 210A may useAPI 205 to obtain the firmware version, frame rate, operatingtemperature, integrated or external display, etc. that hardware 206Aprovides to platform framework 200, also via API 205.

Applications 210A-N may use information provided by platform framework200 entirely outside of it, and/or they may make one or moredeterminations and configure another participant of platform framework200. For example, application 210A may retrieve temperature informationprovided by hardware 206A (e.g., GPU 107), it may determine that anoperating temperature is too high (i.e., above a selected threshold),and, in response, it may send a notification to BIOS 206B via producer207B to configure the IHS's thermal settings according to a thermalpolicy. It should be noted that, in this example, by using API 205,application 210A does not need to have any information or knowledgeabout how to communicate directly with specific hardware 206A and/orBIOS component 206B.

In various implementations, API 205 may be extendable. Once aparticipant subscribes to, or registers with, platform framework 200 viaAPI 205, in addition to standard commands provided by API 205 itself(e.g., get, set, discovery, notify, multicast, etc.), the registeredparticipant may also advertise the availability of additional commandsor services.

For instance, express sign-in and/or session management application210A, thermal policy management application 210B, and privacyapplication 210C may each need to obtain information from one or moreuser presence/proximity sensors (e.g., sensors 112) participating inplatform framework 200 as hardware providers 206A. In this case, theextensibility of API 205 may allow for the abstraction and arbitrationof two or more sensors 112 at the platform framework 200 layer; insteadof having every application 210A-C reach directly into sensors 112 andpotentially crash those devices and/or driver stacks (e.g., due tocontention).

As another example, raw thermal and/or power information may be providedinto platform framework 200 by one or more sensors 112 as hardwareproducers 207A and consumed by two or more applications, such as thermalmanagement application 210A and battery management application 210B,each of which may subscribe to that information, make one or morecalculations or determinations, and send responsive commands to BIOS206C using API 205 in the absence of any specific tools for communicatedirectly with hardware 206A or BIOS 206B.

As yet another example, provider 209A may communicate with anapplication 211A, such as a battery management application or OSservice, and it may set application or OS service 211A to a particularconfiguration (e.g., a battery performance “slider bar”) using API 205without specific knowledge of how to communicate directly with thatapplication or OS service, and/or without knowing what the applicationor OS service is; thus platform framework 200 effectively rendersprovider 209A application and/or OS agnostic.

Within core framework backbone 201, management and oversight engine 202includes services 215A-N within platform framework 200 that may beleveraged for the operation of all participants. Examples of services215A-N include, but are not limited to: registration (e.g., configuredto enable a participant to register and/or advertise data with platformframework 200), notification (e.g., configured to notify any registeredparticipant of a status change or incoming data),communication/translation between user and kernel modes (e.g.,configured to allow code executing in kernel mode to traverse into usermode and vice-versa), storage (e.g., configured to enable any registeredparticipant to store data in session storage database 204), dataaggregation (e.g., configured to enable combinations of various statuschanges or data from the same or multiple participants), telemetry(e.g., configured to enable collection and storage of data usable formonitoring and debugging), arbitration (e.g., configured to enableselection of one among two or more data sources or requests based uponan arbitration policy), manageability (e.g., configured to manageservices 215A-N and/or databases 203/204 of platform framework 200), APIengine (e.g., configured to extend or restrict available commands), etc.

Framework telemetry database 203 may include, for example, anidentification of participants that are registered, data produced bythose participants, communication metrics, error metrics, etc. that maybe used for tracking and debugging platform framework 200. Sessionstorage database 204 may include local storage for sessions establishedand conducted between different participants (e.g., data storage,queues, memory allocation parameters, etc.).

In some implementations, a containerized workspace and/or an applicationexecuted therewithin may participate as a producer (e.g., 207A-N/206A-N)or as a consumer (e.g., 210A-N) of platform framework 200. Particularly,IHS 100 may be employed to instantiate, manage, and/or terminate asecure workspace that may provide the user of IHS 100 with access toprotected data in an isolated software environment in which theprotected data is segregated from: the OS of IHS 100, other applicationsexecuted by IHS 100, other workspaces operating on IHS 100 and, to acertain extent, the hardware of IHS 100. In some embodiments, theconstruction of a workspace for a particular purpose and for use in aparticular context may be orchestrated remotely from the IHS 100 by aworkspace orchestration service. In some embodiments, portions of theworkspace orchestration may be performed locally on IHS 100.

In some embodiments, EC 120 or a remote access controller (RAC) coupledto processor(s) 101 may perform various operations in support of thedelivery and deployment of workspaces to IHS 100. In certainembodiments, EC 120 may interoperate with a remote orchestration servicevia the described out-of-band communications pathways that are isolatedfrom the OS that runs on IHS 100. In some embodiments, a network adapterthat is distinct from the network controller utilized by the OS of IHS100 may support out-of-band communications between EC 120 and a remoteorchestration service. Via this out-of-band signaling pathway, EC 120may receive authorization information that may be used for securedelivery and deployment of a workspace to IHS 100 and to support securecommunication channels between deployed workspaces and variouscapabilities supported by IHS 100, while still maintaining isolation ofthe workspaces from the hardware and OS of IHS 100.

In some embodiments, authorization and cryptographic informationreceived by EC 120 from a workspace orchestration service may be storedto a secured memory. In some embodiments, EC 120 may access such securedmemory via an I²C sideband signaling pathway. EC 120 may supportexecution of a trusted operating environment that supports secureoperations that are used to deploy a workspace on IHS 100. In certainembodiments, EC 120 may calculate signatures that uniquely identifyvarious hardware and software components of IHS 100. For instance,remote EC 120 may calculate hash values based on instructions and otherinformation used to configure and operate hardware and/or softwarecomponents of IHS 100.

For instance, EC 120 may calculate a hash value based on firmware and onother instructions or settings of a component of a hardware component.In some embodiments, hash values may be calculated in this manner aspart of a trusted manufacturing process of IHS 100 and may be stored inthe secure storage as reference signatures used to validate theintegrity of these components later. In certain embodiments, a remoteorchestration service supporting the deployment of workspaces to IHS 100may verify the integrity of EC 120 in a similar manner, by calculating asignature of EC 120 and comparing it to a reference signature calculatedduring a trusted process for manufacture of IHS 100.

EC 120 may execute a local management agent configured to receive aworkspace definition from the workspace orchestration service andinstantiate a corresponding workspace. In this disclosure, “workspacedefinition” generally refers to a collection of attributes that describeaspects a workspace that is assembled, initialized, deployed andoperated in a manner that satisfies a security target (e.g., thedefinition presents an attack surface that presents an acceptable levelof risk) and a productivity target (e.g., the definition provides arequisite level of access to data and applications with an upper limiton latency of the workspace) in light of a security context (e.g.,location, patch level, threat information, network connectivity, etc.)and a productivity context (e.g., performance characteristics of the IHS100, network speed, workspace responsiveness and latency) in which theworkspace is to be deployed. A workspace definition may enable fluidityof migration of an instantiated workspace, since the definition supportsthe ability for a workspace to be assembled on any IHS 100 configuredfor operation with the workspace orchestration service.

In specifying capabilities and constraints of a workspace, a workspacedefinition (e.g., in the form of an XML file, etc.) may prescribe one ormore of: authentication requirements for a user, types of containmentand/or isolation of the workspace (e.g., local application, sandbox,docker container, progressive web application (PWA), Virtual DesktopInfrastructure (VDI)), applications that can be executed in the definedcontainment of the workspace with access to one or more data sources,security components that reduce the scope of the security targetpresented by the productivity environment (e.g., DELL DATA GUARDIAN fromDELL TECHNOLOGIES INC., anti-virus software), the data sources to beaccessed and requirements for routing that data to and from theworkspace containment (e.g., use of VPN, minimum encryption strength),workspace capabilities available to independently attach otherresources, whether or not the workspace supports operability acrossdistinct, distributed instances of platform framework 200 (e.g., byincluding or excluding an identity of another platform framework, or anidentity of another workspace with access to a platform framework).

In some implementations, workspace definitions may be based at least inpart on static policies or rules defined, for example, by anenterprise's Information Technology (IT) personnel. In someimplementations, static rules may be combined and improved upon bymachine learning (ML) and/or artificial intelligence (AI) algorithmsthat evaluate historical productivity and security data collected asworkspaces are life cycled. In this manner, rules may be dynamicallymodified over time to generate improved workspace definitions. If it isdetermined, for instance, that a user dynamically adds a text editorevery time he uses MICROSOFT VISUAL STUDIO from MICROSOFT CORPORATION,then the workspace orchestration service may autonomously add thatapplication to the default workspace definition for that user.

During operation, as an instantiated workspace is manipulated by a user,new productivity and security context information related to thebehavior or use of data may be collected by the local management agent,thus resulting in a change to the productivity or security context ofthe workspace. To the extent the user's behavioral analytics, devicetelemetry, and/or the environment has changed by a selected degree,these changes in context may serve as additional input for areevaluation, and the result may trigger the remote orchestrationservice to produce a new workspace definition (e.g., adding or removingaccess to the workspace as a consumer or producer to an external ordistributed platform framework), extinguish the current workspace,and/or migrate contents of the current workspace to a new workspaceinstantiated based on the new workspace definition.

In some cases, platform framework 200 may be extensible or distributed.For example, different instances or portions of platform framework 200may be executed by different processing components (e.g., processor(s)101 and EC 120) of IHS 100, or across different IHSs. Additionally, oralternatively, independent instances of platform framework 200 may beexecuted by different workspaces and in secure communications with eachother, such that a participant, service, or runtime object's handle mayidentify the particular platform framework 200 that the participant orservice is registered with. Services between these different instancesof platform frameworks may communicate with each other via anInterprocess Communication (IPC) resource specified in a handle providedby the workspace orchestration service for communications with theworkspace(s) involved.

In some embodiments, a workspace definition may specify the platformframework namespaces that a workspace will rely upon. Producers andproviders may be associated with namespaces that are supported by aplatform framework. For example, producers associated with each of thecameras that are available may be registered within a camera namespacethat is supported by platform framework 200. In the same manner,producers and providers that provide user presence detectioncapabilities may be registered within a user presence detectionnamespace that is supported by platform framework 200. Other examples ofnamespaces may include, but are not limited to: a location namespace, aposture namespace, a network namespace, an SoC namespace, etc.

For instance, a workspace definition may specify registration of aworkspace in a user presence detection namespace of the IHS, where userpresence information may be utilized by the workspace in enforcingsecurity protocols also set forth in the workspace definition, such asobfuscating the graphical interfaces of the workspace upon detecting alack of a particular user in proximity to the IHS, thus preserving theconfidentiality of sensitive data provided via the workspace.

In some cases, the workspace definition of a workspace may specify thatthe workspace: instantiate its own a platform framework, use a platformframework instantiated within another workspace (in the same ordifferent IHS), and/or use a combination of different instances ofplatform frameworks (one or more of which may be instantiated by anotherworkspace). Moreover, the platform framework option as prescribed by aworkspace definition may be based upon the resolution of any of theaforementioned contextual rules (e.g., based on IHS posture, location,user presence, etc.).

As used herein, the term “runtime object” refers to a piece of code(e.g., a set of program instructions) or information that can beinstantiated and/or executed in runtime without the need for explicitcompilation. For example, in the context of an arbitration operation,the code that executes the arbitration may already be compiled, whereasthe polic(ies) that the code enforces may change at runtime (e.g., by auser's command in real time) and therefore may be considered “runtimeobjects.”

In various embodiments, systems and methods described herein may provideOS-agnostic runtime object arbitration for platform framework 200.Particularly, these systems and method may provide mechanisms fordefining, registering, and/or receiving notifications of state changesidentified via an arbitration runtime object, for example, based uponthe application of an arbitration policy. In response to these statechanges, platform framework 200 and/or a participant (e.g., 210A-N)receiving the notification may perform modifications to API 205,hibernate IHS 100 and/or suspend its operation, de-register (i.e., evictor free) other arbitration objects, etc.

Using systems and methods described herein, an arbitration object mayregister into platform framework 200 via API 205, receive one or moreruntime objects, and perform an arbitration or selection operation basedupon an arbitration policy. For example, when a location of IHS 100matches an arbitration policy's location rule(s) (that is, when anyapplicable contextual rule is met), the arbitration object may select afirst processor to execute a first video processing operation upon avideo workload. When the IHS location changes, the arbitration objectmay select a second processor to continue processing a remainder of thevideo workload with a different video processing operation or with thesame operation but different processing parameters (e.g., resolution,size, fidelity, etc.). Additionally, or alternatively, when the IHSlocation changes, the arbitration object may select between differentprocessors and/or video processing operations for specific aspects (orlayers) of a video input or workload, such as: virtual backgrounds, livevideo streams, video effects, digital watermarks, shared applicationwindows or documents, etc. The arbitration object may then notifyplatform framework 200 of the arbitration result (or status change), andplatform framework 200 may notify any registered participant (e.g.,210A-N) of the arbitration decision.

Other examples of runtime objects that may be arbitrated in a similarfashion include, but are not limited to: operating temperature objects(from different temperature sensors or different IHS hardwarecomponents), battery metrics objects (e.g., from an OS and a batterymanagement unit), IHS performance objects (e.g., from an OS and anoptimization application), IHS posture objects (e.g., from differentposture sensors), audio capture objects (e.g., an external and aninternal microphone), video capture objects (e.g., from differentcameras), IHS location objects (e.g., from a wireless network interfaceand a GPS sensor), calendar objects (e.g., from a calendar applicationor plugin), etc.

In some cases, platform framework 200 may perform a first arbitrationoperation upon a set of runtime objects for all or most participants(e.g., 210A-N) based upon a first arbitration policy, and one or moredifferentiated arbitration objects may register with platform framework200 (e.g., as applications 210A-N or providers 209A-N) to implement asecond or custom arbitration operation, different from the firstoperation, and made available to other subscribed applications, also viaplatform framework 200.

To that end, API 205 may define an arbitration object including, forexample: a type, a policy and/or conditions, the use of selectedprocessor(s) 101, GPU 107, hardware accelerator, or other SoC cores toexecute conditions, required runtime objects (e.g., from producers207A-N and/or providers 209A-N), states or context of arbitration (IHSposture, application(s) under execution, IHS location, userpresence/proximity, or any combination of context information describedherein), etc.

API 205 may also include a notification command to convey arbitrationresults to subscribed applications, for example, as defined in sessionstorage database 204. A corresponding notification service (e.g., 215A)may be configured to notify a participant in response to certainconditions being met, for example, by executing a notification policythat specifies that a notification event be triggered only in responseto: N state changes (where N is greater than 1), an IHS location, an IHSposture, an IHS temperature, a performance state of IHS 100, a batterycharge level, an application under execution, a user presence state orproximity, a calendar event (e.g., a video communication, a broadcast, avirtual conference, a remote meeting, start and/or end times, duration,participants, participants' roles, etc.).

Contextual actions tied to arbitration policy object state changes mayinclude, but are not limited to: moving or migrating a video workloadto/from CPU 102, moving or migrating a video workload to/from hardwareaccelerator(s) 125, changing a configuration or processing parameter ofa portion of a video workload (e.g., lower or higher resolutionprocessing, omit or add video processing operations, etc.), etc.

In some implementations, a first application may register with platformframework 200 as an arbitration object via API 205 using a specification(e.g., in JavaScript Object Notation or “JSON”) such as:

{ “comments”: “API spec for arbitration object”, “auth_token”:“rt12342d”, “container_id”: “abcd”, “platform_id”: “p5435”,“conditions”: [{ “comments”: “could be ‘simple’ for CPU processing or‘complex’ for instructions to offload core’,  “type”: “simple”,  “handleto policy”: “void *ptr”,  “subsystem”: “UPD”,  “registered object authtokens”: [“t1”, “t2”,....]  }, {  “type”: “complex”,  “handle topolicy”: “void *ptr”,  “subsystem”: “DTT”,  “registered object authtokens”: [“t3”, “t4”,....]  }, {  ...  }] }

An arbitration policy may include, for instance, a set of one or morerules that selects between a CPU 102 and/or one or more offloadprocessor(s) 125 to process video workloads depending upon a context ofIHS 100. In the cases where complex arbitration policies are executed,the API specification of the arbitration object may also select SoCcores to run those policies (e.g., from a hardware accelerator coupledto processor(s) 101 in IHS 100), register IHS 100 state change events,move video workload(s) from IHS 100 to the cloud, to a containerizedapplication, etc.

A second application may register with platform framework 200 to receiveevents from state changes as well as other runtime events determined bythe first application and/or from platform framework 200, such as UPDand other context and/or telemetry changes, by execution of a registeredarbitration policy. Moreover, the second application may performcontextual actions tied to those state changes. In some cases, the firstand second applications may be a single application with a singleplugin.

FIG. 3 is a message diagram illustrating an example of method 300 forplatform framework arbitration, according to some embodiments. In thisexample, method 300 determines whether to use an image sensor object toa TOF sensor object, based upon a location of IHS 100, to calculate auser's proximity to IHS 100. In other implementations, however, method300 may be similarly used to determine whether to process a portion of avideo workload with a first or second one of a plurality of availableprocessors based upon selected contextual trigger(s), and/or whether orhow to apply a watermarking, video/image mirroring, and/or eye directioncorrection policy, as described in more detail below.

As shown, at 306, plugin A 301 (e.g., an instance of PF interface 213)for service A 302 (e.g., an instance of PF-unaware application 212)registers with platform framework 200 as an arbitration object using aservice (e.g., 215A-N) within management and oversight engine 202 viaAPI 205. At 307, service A 302 sends plugin A 301 a message to configurean arbitration policy with an arbitration service (e.g., 215A-N) ofmanagement and oversight engine 202, and at 308, plugin A 301 configuresplatform framework 200 to receive selected runtime objects relevant tothe policy and to execute the policy. Alternatively, service A 302 mayexecute the policy.

At 309, service B 304 (e.g., another instance of PF-unaware application212) sends a command to plugin B 303 (e.g., another instance of PFinterface 213) to register with platform framework 200. At 310, plugin B303 invokes services (e.g., 215A-N) within management and oversightengine 202 of platform framework 200 via API 205 to register andconfigure it to be notified in response to arbitration policy resultsand/or context changes. In some cases, the registration command mayspecify a state or context variable name, an arbitration policy (among aplurality of policies), and/or an arbitration object (e.g., service A302).

In loop 311 (steady state operation), at 312, platform framework 200notifies plugin B 303 that the physical location of IHS 100 istransitioning and/or has changed (e.g., as determined by GPScoordinates, access point signal strength, etc.). At 313, plugin B 303notifies service B 304 of the location transition or change.

At 314, service B 304 computes sensor configuration parameter(s)optimized for operation of a registered image sensor object at the newIHS location (e.g., indoors vs. outdoors, as characterized by ALSreadings, etc.). Then, at 315, service B 304 sends a set command toplatform framework 200 for implementing those computed parameters intothe image sensor's hardware or software through the corresponding imagesensor object, for example, by way of a service (e.g., 215A-N) withinmanagement and oversight engine 202.

At 316, platform framework 200 executes the policy as configured in 308and notifies plugin B 303 of an arbitration state change from imagesensor object to a TOF sensor object, for example, in response to an ALSsensor reading at a new IHS location being above or below a thresholdvalue. At 317, in response to 316, plugin B 303 sends telemetry service305 (e.g., a service 215A-N within management and oversight engine 202)a message to create a state change event in telemetry database 203and/or to send the event to another IHS.

In some embodiments, service A 302 and service B 304 may be the sameapplication (e.g., applications 210A-N or 213). Additionally, oralternatively, service A 302 and service B 304 may be OS services.

In some situations, an application may configure multiple runtimeobjects, for example, by executing unique configuration commands inserial fashion. If a new object or component is added to platformframework 200, however, the application must then get updated to setthat new object. This can be particularly cumbersome in cases when, forexample, IHS 100 moves into a new power or performing state and variousdevices need to be made aware of the change at once.

For instance, in a situation a user may have two applications running onIHS 100, one that performs user detection via low power passive visioncollection and another one that performs network synchronization ofdata. The user may configure IHS 100 into a low performance mode via apower management application. In such a scenario, the power managementapplication would conventionally need to have knowledge of andcommunicate with all registered software applications to alert them ofthe new performance state. Using systems and methods described herein,however, platform framework 200 may be configured to receive such analert from a power management object registered on behalf of the powermanagement application, and, in response, provide indications at once toall applications (e.g., 210A-N or 213) that have been registered toreceive those arbitration results (e.g., that power restrictions arebeing made).

FIG. 4 is a message diagram illustrating an example of method 400 forplatform framework multicasting, according to some embodiments. In thisexample, method 400 multicasts a power notification resulting from theenforcement of a power management policy. In other implementations,however, method 400 may be similarly used to multicast videoorchestration notifications resulting from the enforcement of anintelligent video orchestration policy, such as a watermarking,video/image mirroring, eye direction correction policy, or the like.

As shown, application 401 is registered with platform framework 200. At403, 405, and 407, participants 402A-N (e.g., applications 210A-N) sendregistration commands to API 205, which cause management and oversightengine 202 to add those participants to a list of consumers of an IHSpower status change indication at 404, 406, and 408, respectively.

Application 401 is registered onto platform framework 200, for example,as a provider 209A-N or producer 107A-N. As such, application 401collects runtime objects and/or power configuration options usingdiscovery mechanisms. Upon determination of a need to configure IHS 100into a specific low-power mode at 409, application 401 at 410 makes acall to API 205 to use a notification service (e.g., 215A-N) ofmanagement and oversight engine 202 at 411 to send multicast messages412-414 to all registered participants 402A-N. Lastly, the notificationservice (e.g., 215A-N) may send message 415 to application 401 notifyingit that the multicast even has been completed, its status (e.g., failureor success with respect to a specific participant, etc.).

Large IHS manufacturers (e.g., Original Equipment Manufacturers or“OEMs”) typically produce and support multiple commercial and consumerIHS models, each model having different hardware capabilities. Forexample, a high-end IHS may include a companion die architecture with apowerful offload processor (e.g., hardware accelerator 125), whereas alow-end IHS may have a simpler companion die architecture with a smalleroffload processor. Also, an SoC's capabilities for offloading certainprocessing tasks from a host CPU may vary widely between low-end andhigh-end IHSs.

To enable the intelligent orchestration of video participants inplatform framework 200, systems and methods described herein may providethe ability to: discover normative platform capabilities for SoC andcompanion dies; and enforce the orchestration, manageability, and/orarbitration policies suitable to control which resource (e.g., hostprocessor 102, offload processor 125, etc.) IHS 100 should or may use toprocess a video workload (e.g., live video feed from a camera coupled toIHS 100) or portion thereof in a given context.

For example, in some IHSs equipped with VPUs, the VPU may be usedexclusively for the offloading of AI/ML video processes. In other IHSs,however, the VPU may also be used for video playback.

In various implementations, systems and methods described herein mayenable the registration and configuration (e.g., control APIs, code loadfor offload functionality, I/O data handle configurability, etc.) ofvideo participants, applications, and/or consumers by platform framework200. These systems and methods may also provide for the orchestration ofvideo resources by enforcing certain types of arbitration policies(“intelligent video orchestration policies”) that tie the use of thoseresources to dynamic contextual and/or configuration changes.

For example, if IHS 100 enters a secure location and in response acamera and/or companion die's VPU is disabled, video workloads currentlyexecuted on a VPU may be moved or migrated to another offload core or tothe host CPU, as prescribed by an intelligent video orchestrationpolicy. Additionally, or alternatively, in response to the contextchange, subsequent portions of the video workload may continue to beprocessed by the same processor, but with a corresponding change inconfiguration (e.g., lower fidelity, simpler filtering, less processing,etc.), as prescribed by the intelligent video orchestration policy.

Systems and methods described herein may also enable the dynamicde-registration of one offload core, and in response move a videoworkload to another offload core, as prescribed by an intelligent videoorchestration policy. For example, a simpler segmentation -based virtualbackground replacement performed by a VPU (a first offload core) on acompanion die may be appropriate for general collaborative meetings, buta more computationally-expensive algorithm involving a DNN processor (asecond offload core) may be more suitable for executive-level videopresentations. The type of meeting may be indicated by a calendarapplication or plug-in. In some cases, a video workload may be switchedbetween two or more a VPU and a DNN (or any other suitable offloadprocessor) without tearing down a live or ongoing communication session,as prescribed by an intelligent video orchestration policy.

FIG. 5 is a block diagram illustrating an example of system 500 forintelligent orchestration of video participants in platform framework200, according to some embodiments. For simplicity of explanation,elements such as API 205, orchestrators 108A-N and 211A-N, etc. havebeen omitted. It should be understood, however, that optimizerapplication 506 communicates with services 215A-N of platform framework200 via API 205, and so on, as described in FIG. 2 .

As shown, video source 501 produced by camera 112 (e.g., a live videoinput or feed) by a communication or collaboration application (e.g.,505A) (e.g., a shared desktop, application window, or document) and/orfrom an OS service may provide a signal or frames to be shared during acommunication or collaboration session, for example, after beingprocessed by media foundation engine 502, which in turn may be acomponent of OS 206C. Particularly, media foundation engine 502 mayapply any number of video processing operations 503A-N to video source501 in any selected order and with any selected configurationparameters.

Examples of video processing operations 503A-N include, but are notlimited to: user or subject/presenter framing, resolution change, zoomin/out, lighting correction, virtual background, filtering, digitalwatermarking, eye contact correction, video/image mirroring, etc. Insome cases, media foundation engine 502 and/or each video processingoperation 503A-N may have a respective agent, driver, and/or plugin(e.g., 207C) registered with platform framework 200.

CPU 504A, GPU 504B, GNA 504C, and VPU 504N are examples of hardwaredevices 206A registered with platform framework 200. Each of processorsand/or cores 504A-N may be available to processor some aspect of videoinput 501. For example, each of processors and/or cores 504A-N may beconfigured to perform one or more of video processing operations 503A-Nat the behest of media foundation engine 502 and/or video consumers505A-N. In some cases, one or more of processors and/or cores 504A-N maybe part of a different companion die architecture (re-discoverable uponboot).

Video consumers 505A-N are examples of applications 210A-N registeredwith platform framework 200 and may include any application thatreceives video input 501 and/or processed video workloads. Examples ofvideo consumers 505A-N include, but are not limited to, videoconferencing applications, remote collaboration applications (e.g.,SKYPE, ZOOM, TEAM, WEBEX, etc.). In some cases, one or more of videoconsumers 505A-N may also be configured to perform or request their ownvideo processing operation(s), otherwise similar to video processingoperations 503A-N, using processors and/or cores 504A-N.

Optimizer application 506 is yet another instance of applications210A-N, and it may register with platform framework 200 to perform oneor more optimization operations, for example, based upon one or morepolicies (e.g., arbitration policies, such as an intelligent videoorchestration policy), as described in FIG. 3 . To that end, intelligentvideo plugin 507A may provide a user interface that allows a user toselect one or more video features or options, and/or to select one ormore policies that, upon enforcement, enable the intelligentorchestration of video participants 502, 504A-N, 505A-N, and/or 506 viaplatform framework 200. Other plugins 507B-N may include softwaremodules configured to communicate with other applications (e.g., acalendar application to retrieve impending or upcoming events), RightsManagement Services (RMS) (e.g., using a MICROSOFT AZURE INFORMATIONPROTECTION plugin or the like), and/or other sources of contextinformation (e.g., sensors 112) that may not themselves be directlyregistered with platform framework 200 via API 205.

FIG. 6 is a block diagram illustrating an example of method 600 forintelligent orchestration of video participants 502, 504A-N, 505A-N,and/or 506 via platform framework 200. In some embodiments, method 600may be performed, at least in part, by optimizer application 506 and/orintelligent video plugin 507A in cooperation with platform framework200.

At 601, intelligent video plugin 507A enters its initialization state.At 602, intelligent video plugin 507A receives from remote service 603an intelligent video orchestration policy tying certain video processingoperations and/or types of video processing operations to particularprocessors or types of processors (e.g., GPU, VPU, etc.) in response toa given context a change such as, for example: a change in a presence orproximity of a user, a location of IHS 100, a power state, a batterycharge of the IHS, a current, upcoming, or impending calendar event,etc. In some cases, the intelligent video orchestration policy may beassigned to IHS 100 based upon a service tag, certificate, encryptionkey, RoT, or other suitable IHS identification.

At 604, intelligent video plugin 507A registers with platform framework200 via API 205. At 605, intelligent video plugin 507A registers withoptimizer application 506. At 606, intelligent video plugin 507A queriesplatform framework 200 for information about other video participants'capabilities (e.g., media foundation engine 502, CPU 504A, GPU 504B, GNA504C, VPU 504N, video consumers 505A-N, etc.). At 607, platformframework 200 returns the queried information to intelligent videoplugin 507A.

At 608, intelligent video plugin 507A matches video participants'capabilities against one or more rules in the intelligent videoorchestration policy, depending upon the initial context of IHS 100.Particularly, at 608 intelligent video plugin 507A may identify, basedupon the intelligent video orchestration policy, which video processingoperations to offload to which cores, including data I/O, code load,etc.

At 609, intelligent video plugin 507A configures usable capabilities ofselected video participants and registers to receive notifications fromthose participants, for example, indicating a change in coreconfiguration, core status (such as cores running out cycles), corede-registration, etc. via platform framework 200. At 610, intelligentvideo plugin 507A registers with platform framework 200 for provider(e.g., 209A-N) notifications (e.g., with arbitration of results orcombination data from multiple sensors, camera disablement, etc.). Then,at 611, intelligent video plugin 507A configures contextual events foroptimizer application 506 to listen for (e.g., from other plugins507B-N) contextual changes such as changes in a presence or proximity ofa user, a location of IHS 100, a power state, a battery charge of theIHS, a current or impending calendar event, etc.

During loop or steady state operation 612, at 613, platform framework200 notifies intelligent video plugin 507A of any present changes in theusable capabilities for offloading video workloads to participants504A-N, for example. For instance, platform framework 200 may notifyintelligent video plugin 507A that VPU 504N on the companion die isgetting shut off due to the camera entering a privacy mode (e.g., as IHS100 enters or leaves a secure location) or that VPU 504N is getting shutoff due to the camera leaving the privacy mode (e.g., as IHS 100 entersor leaves the secure location).

At 614, intelligent video plugin 507A computes new usable capabilitiesfor offload settings based on the intelligent video orchestrationpolicy, taking change 613 into account. In response, intelligent videoplugin 507A configures new usable capabilities for offload settings toplatform framework 200 at 615. For example, intelligent video plugin507A may move a video workload or a portion thereof from VPU 504N to CPU102 or vice-versa. Additionally, or alternatively, intelligent videoplugin 507A may change a processing parameter (e.g., pixel resolution,frame rate, etc.) of a portion of the workload.

At 616, optimizer application 506 notifies intelligent video plugin 507Aof a contextual change(s) to IHS 100. In response, at 617, intelligentvideo plugin 507A computes a change in session settings, and at 618intelligent video plugin 507A sends a message to platform framework 200to configure the remainder of the session and/or to change settings tiedto the companion die accordingly.

As an example, at 616, optimizer application 506 notifies intelligentvideo plugin 507A, using a calendar/agenda plugin (e.g., 507B) and/orvia an API directly with video consumers 505A-N, that a change ofpresenter during a collaboration session is about to take place (e.g.,an executive is going to give a speech, or has just finished giving thespeech). Additionally, or alternatively, optimizer application 506 maynotify intelligent video plugin 507A, using a power management plugin(e.g., 507C) that a low Relative State-Of-Charge (RSOC) notification(e.g., remaining battery level at X %) has been received, thustriggering a reduction in power consumption of IHS 100. In response, at618, platform framework 200 may increase or reduce the complexity of thevideo workload (e.g., pixel resolution, frame rate, number or order ofvideo processing operations, etc.). As another example, a change oflocation may require a different virtual background and/or matting tosegmentation switch in one of a plurality of offload cores.

Accordingly, systems and methods described herein may provide foradaptive platform orchestration across IHS lines of varying capabilitiesfor intelligent collaboration. Moreover, these systems and methods mayadaptively scale platform compute based on SoC and application and/orcontextual events.

In modern work environments, and particularly since the COVID-19pandemic, more workers than ever have been performing their jobsremotely using communication or collaboration applications (e.g., SKYPE,ZOOM, TEAM, WEBEX, etc.) to conduct their day-to-day business. As aconsequence, these remote workers are now sharing an ever-increasingnumber of electronic documents, spreadsheets, and presentations ininternal and external meetings—some of which may include sensitive,secret, copyrighted, privileged, and/or confidential information.

In some embodiments, systems and methods described herein may increasethe security and protection of sensitive, secret, copyrighted,privileged, and/or confidential content which, during a communication orcollaboration session (e.g., a live or recorded presentation), mayotherwise be subject to screenshots or other forms of unauthorizedcopying by participants of the session. For example, systems and methodsdescribed herein may use platform framework 200 to leverage RMS and dataclassification tools to label electronic documents in order to protectmaterial classified for internal use, restricted, or highly restrictedwhen such material is shared in a communication or collaborationsession.

Moreover, these systems and methods may intelligently apply and/orremove digital watermarking to selected portions of content shared orbroadcast in a communication or collaboration session (e.g., sharedvideo, document, application window, desktop, etc.) via platformframework 200 based upon the enforcement of a watermarking policy usingcontext information (e.g., document classification, IHS location, etc.).In other embodiments, systems and methods may intelligently apply and/orremove digital watermarking to selected portions of content processed byother types of applications, such as an image capture application, orany other application executed outside of a collaboration environment.

In some cases, a digital watermark may include a company logo, acopyright statement, and/or any other visual element indicative ofproperty or ownership (e.g., intellectual property, secret, etc.).Additionally, or alternatively, participants' names, email addresses,usernames, phone numbers, etc. may be included in the digital watermarkto identify persons taking part in the communication or collaborationsession. As used herein, the term “digital watermark” refers to a visualmarker embedded in a noise-tolerant signal or content such as audio,video, or image data and usable to identify ownership or the copyrightof such content.

FIG. 7 is a block diagram illustrating an example screenshot 700 ofwatermarks introduced into a communication or collaboration session by awatermarking service using intelligent orchestration of videoparticipants 502, 504A-N, 505A-N, and/or 506 via platform framework 200.For example, optimizer application 506 and/or intelligent video plugin507A may include a watermarking service configured to interface with acalendar plugin (e.g., 505B) and/or an RMS plugin (e.g., MICROSOFT AZUREINFORMATION PROTECTION or 505C) to enforce a watermarking policy based,at least in part, upon context information.

As shown, screenshot 700 represents a communication or collaborationapplication (e.g., 505A) window during a communication or collaborationsession between two or more participants. In screenshot 700, theapplication window comprises shared document, application window, ordesktop portion 701 and shared camera and/or video feed portion 703. Anyof digital watermarks 702A-N may be applied to shared document,application window, or desktop portion 701. Additionally, oralternatively, digital watermark 704 may be applied to video feedportion 703.

To apply a digital watermark, optimizer application 506 and/orintelligent video plugin 507A may request, via platform framework 200,that media foundation engine 502 execute a corresponding one of videoprocessing operations 503A-503N to add a video layer or image overlayupon one or more frames of video source 501 (e.g., from camera 112, froma communication or collaboration application, from the OS, etc.)containing the digital watermark using one or more of processors 504A-Nas prescribed by the watermarking policy. The watermarked output ofmedia foundation engine 502 is sent to a communication or collaborationapplication 505A prior to being shared or broadcast during a session.

In some cases, certain characteristics of digital watermarks 702A-Nand/or 704 may be prescribed by the watermarking policy and may varybased upon context information (e.g., classification of the content, anoriginator of the content, a type of the communication session, aparticipant of the communication session, IHS location, etc.). Examplesof characteristics may include but are not limited to: details of thedigital watermark (e.g., one or more names of participants of thecommunication session retrieved from a calendaring or agenda applicationor plugin, reference to a non-disclosure agreement (NDA) or othergoverning legal document retrieved from an email or document managementapplication or plugin, etc.), size of the digital watermark, position ofthe digital watermark, and number of digital watermarks.

Although screenshot 700 shows a specific configuration of sharedcontent, it should be noted that variations are within the scope of thisdisclosure. For example, in some cases, shared document, applicationwindow, or desktop portion 701 may be absent. In other cases, sharedcamera and/or video feed portion 703 may be absent. Additionally, oralternatively, any number of shared document, application window, ordesktop portions 701 or shared camera and/or video feed portions 703 maybe displayed. Additionally, or alternatively, the position and relativesize of any given portion of screenshot 700 may be configurable.

FIG. 8 is a block diagram illustrating an example of watermarking method800 executed by a watermarking service using intelligent orchestrationof video participants 502, 504A-N, 505A-N, and/or 506 via platformframework 200. In some embodiments, method 800 may be performed, atleast in part, by optimizer application 506 and/or intelligent videoplugin 507A (a “watermarking service”) in cooperation with platformframework 200.

Method 800 starts at 801. At 802, optimizer application 506 isinitiated. At 803, a communication or collaboration session isestablished between two or more users, for example, by one of videoconsumer or application 505A. At 804, optimizer application 506determines whether a watermarking service provided by intelligent videoplugin 507A is enabled. If not, 809 determines whether a document isbeing shared. If not, 813 determines whether the communication orcollaboration session has ended. If so, method 800 ends at 814.

At 804, if the watermarking service is enabled, control passes to 805,where method 800 retrieves session users (e.g., names of peopleparticipating in the communication or collaboration session) using anAPI supported by video consumer or application 505A (e.g., a ZOOM API).Additionally, or alternatively, session users may be identified using acalendar or agenda application plugin 507B or RMS plugin 507C.Additionally, or alternatively, reference to an NDA or other legaldocument governing the ownership and/or dissemination of information maybe identified using an email application plugin or document managementapplication plugin.

The aforementioned information, as well as a logo(s), graphics, companyname(s), document classification, size, format, and position of adigital watermark may be stored in session storage database 204 at 806.At 807, method 800 retrieves the information from session storagedatabase 204 and use that information to generate and add watermark 704to video stream 704 before it is shared during the communication orcollaboration session. Particularly, at 807, method 800 may identify awatermarking policy and use that policy to determine whether to apply adigital watermark to a portion of a video workload based upon contextinformation such as: an originator of the video, a subject of the video,a type of the communication session, or a participant of thecommunication session.

Still at 807, method 800 may generate and apply digital watermark 704 tovideo content 703, the digital watermark having characteristics (detailsof the digital watermark, size of the digital watermark, position of thedigital watermark, number of digital watermarks, etc.) selected basedupon the application of additional context information collected viasensors 112 to the watermarking policy. The additional contextinformation may include one or more of: a user's presence or proximitystate, a facial expression of the user, a direction and focus of theuser's gaze, a user's hand gesture, a user's voice, an IHS location, IHSmovement, lid state, hinge angle, IHS posture, whether the IHS iscoupled to a dock or docking station, a distance between the user and atleast one of: the IHS, the keyboard, or a display coupled to the IHS, atype of keyboard being used, whether the user operating the keyboard istyping with one or two hands, a time of day, software application(s)under execution in focus for receiving keyboard input, whether IHS 100is inside or outside of a carrying bag or case, a level of ambientlighting, a battery charge level, whether IHS 100 is operating frombattery power or is plugged into an AC power source, a power mode orrate of power consumption of various components of IHS, etc.

At 808, method 800 may set a callback with video consumer or application505A to be notified of an application, window, or desktop sharing eventusing an API supported by video consumer or application 505A (e.g., aZOOM API). At 809, if the event callback is received, control passes to810.

At 811, method 800 determines a document, application, or desktopclassification (e.g., privacy or sensitivity level, for example, basedon an RMS query or the like). At 806, method 800 stores the documentclassification information in session storage database 204. Then, at812, method 800 may determine whether to apply a digital watermark702A-N to a portion of shared document, application, or desktop 701based upon context information such as: an originator of the document,application, or desktop, a type of the communication session, or aparticipant of the communication session.

Method 800 generates and applies additional digital watermark(s) 702A-Nto document, application window, or desktop portion 701, the digitalwatermark having characteristics (details of the digital watermark, sizeof the digital watermark, position of the digital watermark, number ofdigital watermarks, etc.) selected based upon the application ofadditional context information collected via sensors 112 to thewatermarking policy. The additional context information may include oneor more of: including one or more of: a user's presence or proximitystate, a facial expression of the user, a direction and focus of theuser's gaze, a user's hand gesture, a user's voice, an IHS location, IHSmovement, lid state, hinge angle, IHS posture, whether the IHS iscoupled to a dock or docking station, a distance between the user and atleast one of: the IHS, the keyboard, or a display coupled to the IHS, atype of keyboard being used, whether the user operating the keyboard istyping with one or two hands, a time of day, software application(s)under execution in focus for receiving keyboard input, whether IHS 100is inside or outside of a carrying bag or case, a level of ambientlighting, a battery charge level, whether IHS 100 is operating frombattery power or is plugged into an AC power source, a power mode orrate of power consumption of various components of IHS, etc.

Accordingly, systems and methods described herein may provide a servicethat intelligently adds digital watermarks to both the webcam stream aswell as any shared documents using an RMS classification system toprotect sensitive materials during communication or collaborationsessions.

In communication or collaboration sessions that employ video, a videofeed or broadcast often includes a plurality of components or layers.For example, a given video feed may include a live camera feed, avirtual background layer, a document, an overlayed text or image, anapplication window, a shared desktop, etc. These various components orlayers may be combined into a single video stream by a broadcasting IHSand transmitted to other IHSs participating in the communication orcollaboration session.

When different video components or layers are combined, however,sometimes one or more of them may be inadvertently flipped with respectto other ones, as evidenced in later-watched recordings of thecommunication or collaboration session. For example, sometimes a virtualbackground with text in it may need to be flipped in the left-to-right(L-R) orientation (or “mirroring”). Whether the virtual background is animage or video sequence, the user may not always be able to simply flipthe image L-R and store it, for instance, if same image is used acrossmultiple communication or collaboration applications where the sameadjustment does not solve the inadvertent mirroring problem. Moreover,the user may desire to have the correct playback L-R orientation shownwhen playing back a communication or collaboration session recording.

As another example, a communication or collaboration application mayhave a “mirror my video” (L-R orientation) option that, when selected bya user, allows the user to preview their video correctly prior tosharing it over a communication or collaboration session. In thepreview, virtual backgrounds with text are reversed. If the userresponds by manually flipping and storing them in reverse orientationsduring the preview, these elements will appear reversed during the livecommunication or collaboration session.

To address these, and other concerns, systems and methods describedherein may resolve and/or arbitrate inconsistencies between IHSs and IHSconfigurations (e.g., front-facing camera vs. back-facing camera;video/camera shows a mirrored image to user when recording, but onlystores video with flipped orientation for playback; different settingsand options for capturing or recording images as mirrored or unmirrored;etc.) that would otherwise make it difficult to orchestrate the properorientation or mirroring of video components or layers shared during acommunication or collaboration session.

In some embodiments, the decision of whether to flip a given videocomponent or layer (e.g., a live camera feed, a virtual backgroundlayer, a document, an overlayed text or image, an application window, ashared desktop, etc.) may be made by optimizer application 506 and/orintelligent video plugin 507A based on a video/image mirroring policyenforced, at least in part, via platform framework 200. The video/imagemirroring policy may include one or more rules for deciding whether tochange the orientation of a given component or layer of a video streamto be shared or broadcast based on contextual information (e.g., IHSlocation, IHS posture, user proximity, etc.).

As used herein, the term “orientation” refers to a Left-to-Right (L-R),Right-to-Left (R-L), Top-to-Bottom (T-B), and/or Bottom-to-Top (B-T)orientation with respect to a center horizontal or vertical axis. Tochange the orientation of a video component or layer, an image transform(e.g., video processing operation 503A) may be applied to one or moreframes of the video component or layer so as to flip the orientation ofpixels in those frames around its horizontal or vertical center axis,depending upon context, as prescribed by a video/image mirroring policy.

In some cases, the image transform may be applied by media foundationengine 502 executed by a selected one or more of processor(s) 501A-N.Additionally, or alternatively, the image transform may be applied byone or more video consumer(s) 502A-N (e.g., a communication orcollaboration application).

FIGS. 9A and 9B are screenshots 900A and 900B of examples of sharedcontent subject to video/image mirroring, according to some embodiments.Particularly, in screenshot 900A, video capture portion or layer 902F isL-R flipped, virtual background portion or layer 901 is not flipped, andwatermark portion or layer 903 is also not flipped. In screenshot 900B,video capture portion or layer 902 is correct, but virtual backgroundportion or layer 901F is L-R flipped, and watermark portion or layer903F is also L-R flipped.

To correct the orientation of any given content portion or layer 901F,902F, and/or 903F, a video and/or image mirroring service may apply animage transform to flip that portion or layer around a horizontal orvertical center axis, based upon context (e.g., classification ofcontent, identity or role of an originator of content, type of thecommunication session, identification or proximity of a participant ofthe communication session, IHS location, IHS posture, whether a camerasource is front-facing or rear-facing with respect to the IHS,identification of a communication or collaboration applicationconfigured to establish the communication session, etc.). In some cases,a video/image mirroring policy may require that a given image or layersuch as, for example, virtual background portion or layer 901F and/orwatermarking layer 903F, be flipped prior to being combined into a videostream.

FIG. 10 is a flowchart illustrating an example of method 1000 forintelligent orchestration of video/image mirroring using platformframework 200. In some embodiments, method 1000 may be performed, atleast in part, by optimizer application 506 and/or intelligent videoplugin 507A (a “video/image mirroring service”) in cooperation withplatform framework 200.

Method 1000 begins at 1001. At 1002, method 1000 loads manageabilityconfigurations including, for example, a video/image mirroring policy.In some cases, a video/image mirroring policy may have a format such as:{“UC”:“zoom”, “virt_bg”:“LR flip”, “video capture”:“no flip”, “recordedplayback”:“LR flip”} (a JSON example).

At 1003, a service (e.g., 215A-N) may watch for the initiation ofcommunication or collaboration process by any registered video consumer(e.g., 505A-N) and/or a change of event such as user changing an activevirtual background, changing an IHS posture, switching between afront-facing and a rear-facing camera, etc. Upon detection, the service(e.g., 215A-N) may notify the video/image mirroring service to load andenforce the video/image mirroring policy at 1004.

At 1005, the video/image mirroring policy may indicate to thevideo/image mirroring service how to configure each of video consumers(e.g., 505A-N) to account for any orchestrated change in context and/ororientation using north side APIs. Moreover, the video/image mirroringpolicy may indicate to the video/image mirroring service how toconfigure processors 504A-N and/or media foundation engine 502 via southside APIs. For example, control level APIs may include IPU6 based L-Rvideo camera input flip (MIPI), virtual background flip, playbackflip/normal, etc. Method 1000 ends at 1006.

In various implementations, the video/image mirroring policy may includeone or more rules. When context information matches the requirementsprescribed by a given rule, that rule is triggered or met, thuseffecting (or foregoing) a change in orientation of at least a portionof the content.

For example, when a virtual background L-R flip is effected on the southside (e.g., by media foundation engine 502), video consumer 505A may beinstructed to have its virtual background disabled since it has alreadybeen multiplexed into the capture stream. In some cases, video/imagemirroring policies may be combined and/or stored together with otherpolicies (e.g., a watermarking policy, an eye direction correctionpolicy, etc.) tied to the overall manageability of intelligentcommunication or collaboration sessions.

In some implementations, a video/image mirroring policy may be specificto an IHS 100's stock-keeping unit (SKU). The policy's video capture andrecording/playback orientation rules may be individually configured foreach different video consumer application 505A-N. Additionally, oralternatively, a user may be prompted intelligent video plugin 507 toselect L-R configurations for virtual backgrounds or other content asthey start one of video consumer application 505A-N.

Accordingly, systems and methods described herein may adaptively setvideo/image mirroring with captured video, virtual background, recordingstate, etc. for intelligent collaboration user experience. Moreover,these systems and methods may enable the contextual rotation of virtualbackground or other content based on IHS postures, content of videostream, etc.

In many situations, whether in a video conference or recorded videosession, a user often finds themselves interacting directly with afront-facing video camera mounted on their IHS's primary display—e.g.,looking straight at the display's built-in or attached camera—whileoccasionally and/or periodically looking at content on and off theprimary display, for instance, on a secondary display. During a typicalcommunication or collaboration session, a user's gaze may continuallychange, at times looking directly at a camera, and at other timeslooking away from that camera and towards content. For example, contentmay be located on (a lower portion of) the primary display, on asecondary display, on another IHS, on a whiteboard, etc., or it may be aphysical object, exhibit, sample, etc.

To viewers or other participants of the video conference, a presenter'sfrequent change of gaze with respect to the front-facing video cameracan have a distracting effect (similar to when a newscaster is lookingat the wrong camera during a news broadcast on television). To addressthis, systems and methods described herein may employ two or morecameras to maintain user eye contact during a communication orcollaboration session as a user's gaze changes direction, for example,by automatically switching between video feeds produced by the twocameras based upon an evaluation of a weighted average gaze vector.

In some cases, the weighted gaze vector may be based upon a combinationof gaze vectors calculated using images from each camera. The gazevector (g) processed from each camera may be multiplied by a respectivecontextual factor or weight (a) selected based upon at least one of: adirection of a sound detected with two or more microphones, an angle ofarrival or an angle of departure of a wireless device (e.g., usingBLUETOOTH 5.1), a proximity of a presenter to a given camera (e.g., theclosest to a given camera the user is, the greater the weight assignedto a gaze vector from that camera and/or the farther from a given camerathe user is, the smaller the weight assigned to a gaze vector from thatcamera), a specification of a given one of the plurality of cameras(e.g., the greater the resolution of a given camera, the greater theweight assigned to a gaze vector from that camera and/or the smaller theresolution a given camera, the smaller the weight assigned to a gazevector from that camera), a user preference or setting, etc.

An example of user preference or setting may include a user's preferencefor a primary camera over a secondary camera that increases an amount oftime the primary camera is used (e.g., over the secondary camera) toshare its video feed during a communication or collaboration session.Additionally, or alternatively, the user preference or setting may applya hysteresis setting that increases an amount of time required beforewhich a change of direction of the weighted gaze vector, maintained at avalue greater than a selected threshold value, triggers a correspondingchange of camera and/or video feed during a communication orcollaboration session.

In some implementations, to apply the eye contact correction operation,IHS 100 may determine whether and/or how to enforce an eye contactcorrection policy via platform framework 200 based, at least in part,upon context information. Such context information may include, forexample: a classification of the video being shared (or other contentsubject to the user's gaze), an identity or role of an originator of thevideo or content, a type of the communication session, an identificationof an application configured to establish the communication session(and/or to provide the other content subject to the user's gaze), an IHSlocation, an IHS posture, etc.

The decision of whether and/or when to switch a video input between twoor more camera sources may be made by optimizer application 506 and/orintelligent video plugin 507A based on the eye contact correction policy(e.g., an arbitration policy) via platform framework 200. An eye contactcorrection policy may include one or more rules for deciding whether tochange the source of a video stream to be shared or broadcast based oncontextual information. Additionally, or alternatively, an eye contactcorrection policy may include one or more rules for deciding whetherand/or how to apply a user framing operation (e.g., video processingoperation 503A of media foundation engine 502).

FIG. 11 is a diagram of an example of system 1100 for eye contactcorrection in a communication or collaboration session using platformframework 200. As shown, user 1101 operates IHS 100A coupled tosecondary display or IHS 100B. In this configuration, IHS 100B displaysa video feed of another user participating in the communication orcollaboration session, whereas IHS 100A displays other content (e.g.,documents, presentations, materials shared during the session, etc.).IHS 100A includes front-facing camera 112A and webcam 112B is mounted onIHS/display 100B.

In some cases, both front-facing camera 112A and webcam 112B may becoupled to IHS 100A and registered with platform network 200. In othercases, webcam 112 may be coupled to IHS 100B and registered with aplatform network 200 distributed between IHSs 100A and 100B. Althoughsystem 1100 shows two IHSs 100A and 100B, each having a respectivedisplay, and two cameras 112A and 112B, it should be understood thatsystems and methods described herein are scalable to any number of IHSs(one or more), cameras (two or more), or displays (if any).

In system 1100, when user 1101 is looking toward IHS 100A, as determinedby a weighted average of gaze vector(s) 1102A and 1102B, the video feedfrom front-facing camera 112A may be shared over the communication orcollaboration session. Conversely, when user 1101 is looking toward IHS100B, as determined by a weighted average of gaze vector(s) 1102A and1102B, the video feed from webcam 112B may be shared over thecommunication or collaboration session. To make these determinations,the weighted average gaze vector may be calculated using gaze vector(s)1102A and/or 1102B as well as any of the aforementioned contextualinformation as individual weights associated with each video source orcamera. Moreover, the weighted average gaze vector may also be used toperform a user framing operation or the like.

FIG. 12 is a flowchart of an example of method 1200 for eye contactcorrection in a communication or collaboration session using platformframework 200. In some embodiments, method 1200 may be performed, atleast in part, by optimizer application 506 and/or intelligent videoplugin 507A (an “eye contact correction service”) in cooperation withplatform framework 200.

Method 1200 begins at 1201. At 1202, a user starts a communication orcollaboration application (e.g., 505A), such that platform 200 getsnotified via API 205. At 1203, IHS 100 processes a video frame, forexample, using media foundation engine 302. At 1204, method 1200determines whether gaze and/or head-related transfer function (HRTF, aresponse that characterizes how an ear receives a sound from a point inspace) is enabled, for example, by enforcement of an eye contactcorrection policy by optimizer application 506 and/or intelligent videoplugin 507A in conjunction with platform framework 200.

If the eye contact correction policy does not apply (e.g., contextualrules are not met), then 1205 loads standard camera API settings andcontrol passes to block 1213. Otherwise, if the eye contact correctionpolicy applies (e.g., at least one contextual rule requiring eye contactcorrection is met), at 1206 optimizer application 506 receives a gazevector from each of a plurality of cameras registered with platformframework 200 via API 205, as well as any intrinsic or preset weightvalues associated with each camera and/or gaze vector, for example, asprovided in the eye contact correction policy.

In some embodiments, eye contact correction method 1200 may be based onthe fusion of multiple sensors: multiple sensor stacks may be used todetermine a user's gaze vector (CVF, etc.), such as, for example, audioinput direction from microphone sources, as shown in 1207, and BLUETOOTH5.1 angle of arrival and/or angle of departure direction(s) from aheadset's operation, as shown in 1209.

Particularly, at 1207, method 1200 determines if a microphone array ison and/or registered with platform framework 200. If so, 1208 modifies aweight to be given to at least one of the gaze vectors based upon adifference between the direction of the user's gaze and the direction oftheir speech. At 1209, method 1200 determines if a BLUETOOTH 5.1 headset(or other wireless device with like capabilities) is on and/orregistered with platform framework 200. If so, 1210 modifies a weight tobe given to at least one of the gaze vectors based upon a differencebetween the direction of the user's gaze and the direction of theheadset's angle of arrival and/or departure.

Additionally, or alternatively, method 1200 may modify a weight to begiven to at least one of the gaze vectors based upon directionalinformation obtained from a time-of-flight (ToF) sensor(s).Additionally, or alternatively, method 1200 may modify a weight to begiven to at least one of the gaze vectors based upon the aforementionedcontextual information.

At 1211, method 1200 calculates and/or updates the value of a weightedaverage gaze vector (g_(ave)) by taking in gaze vector inputs (x_(i),y_(i), z_(i)) from n sources or cameras and applying a weight to eachgaze vector to calculate single most accurate gaze vector. For example,in the case of two cameras or video sources (n=2):

g _(ave) =α*g _(A)+(1−α)*g _(B)

where g_(i)=(x_(i), y_(i), z_(i)), and α=weight from 0.0 to 1.0.

In some embodiments, weight α may be an intrinsic weight based oncalibrated accuracy and/or on the resolution of different cameras and/orother sensor inputs. This weight may be enhanced by operations 1208,1210, and/or other context information as prescribed by the eye contactcorrection policy.

At 1212, optimizer application 506 and/or intelligent video plugin 507Asends an updated weighted average gaze vector (g_(ave)) to thecommunication or collaboration application (e.g., 505A), which in turnmay switch the video feed between different cameras based upon adifference between the direction of the user's weight averaged gazevector g_(ave) and the relative positions of the different cameras(e.g., left or right, up or down, etc.). Additionally, or alternatively,optimizer application 506 and/or intelligent video plugin 507A mayselect the camera with which the user has best eye contact based on theweighted average gaze vector (g_(ave)), and it may notify thecommunication or collaboration application of its selection.

At 1203, method 1200 determines whether the user has ended thecommunication or collaboration session. If not, control returns to 1203.If so, method 1200 ends at 1214.

Accordingly, systems and methods described herein may enable theapplication of a weighted average to multiple eye gaze sensors as amethod to determine camera-based gaze correction. Additionally, oralternatively, these systems and methods may enable the application ofaudio direction as weight for determining eye gaze direction.Additionally, or alternatively, these systems and methods may enable theapplication BT 5.1 angle of arrival and/or angle of departure methods asinput weight for determining head position and/or eye gaze direction.

It should be understood that various operations described herein may beimplemented in software executed by processing circuitry, hardware, or acombination thereof. The order in which each operation of a given methodis performed may be changed, and various operations may be added,reordered, combined, omitted, modified, etc. It is intended that theinvention(s) described herein embrace all such modifications and changesand, accordingly, the above description should be regarded in anillustrative rather than a restrictive sense.

The terms “tangible” and “non-transitory,” as used herein, are intendedto describe a computer-readable storage medium (or “memory”) excludingpropagating electromagnetic signals; but are not intended to otherwiselimit the type of physical computer-readable storage device that isencompassed by the phrase computer-readable medium or memory. Forinstance, the terms “non-transitory computer readable medium” or“tangible memory” are intended to encompass types of storage devicesthat do not necessarily store information permanently, including, forexample, RAM. Program instructions and data stored on a tangiblecomputer-accessible storage medium in non-transitory form may afterwardsbe transmitted by transmission media or signals such as electrical,electromagnetic, or digital signals, which may be conveyed via acommunication medium such as a network and/or a wireless link.

Unless stated otherwise, terms such as “first” and “second” are used toarbitrarily distinguish between the elements such terms describe. Thus,these terms are not necessarily intended to indicate temporal or otherprioritization of such elements. The terms “coupled” or “operablycoupled” are defined as connected, although not necessarily directly,and not necessarily mechanically. The terms “a” and “an” are defined asone or more unless stated otherwise. The terms “comprise” (and any formof comprise, such as “comprises” and “comprising”), “have” (and any formof have, such as “has” and “having”), “include” (and any form ofinclude, such as “includes” and “including”) and “contain” (and any formof contain, such as “contains” and “containing”) are open-ended linkingverbs. As a result, a system, device, or apparatus that “comprises,”“has,” “includes” or “contains” one or more elements possesses those oneor more elements but is not limited to possessing only those one or moreelements. Similarly, a method or process that “comprises,” “has,”“includes” or “contains” one or more operations possesses those one ormore operations but is not limited to possessing only those one or moreoperations.

Although the invention(s) is/are described herein with reference tospecific embodiments, various modifications and changes can be madewithout departing from the scope of the present invention(s), as setforth in the claims below. Accordingly, the specification and figuresare to be regarded in an illustrative rather than a restrictive sense,and all such modifications are intended to be included within the scopeof the present invention(s). Any benefits, advantages, or solutions toproblems that are described herein with regard to specific embodimentsare not intended to be construed as a critical, required, or essentialfeature or element of any or all the claims.

1. An Information Handling System (IHS), comprising: a processor; and amemory coupled to the processor, the memory having program instructionsstored thereon that, upon execution, cause the IHS to: receive anotification, via a platform framework, of a communication session; andin response to the notification, apply a video or image mirroringoperation, via the platform framework, to only a portion of contentshared during the communication session, wherein the video or imagemirroring operation changes the orientation of the portion of thecontent.
 2. The IHS of claim 1, wherein the communication sessioncomprises at least one of: a video communication, a broadcast, a virtualconference, or a remote meeting.
 3. The IHS of claim 1, wherein thecontent comprises at least one of: a live video feed, a recorded video,a virtual background, a watermark, a shared desktop, a sharedapplication window, or a shared document.
 4. The IHS of claim 1, whereinto apply the video or image mirroring operation, the programinstructions, upon execution, cause the IHS to apply a left-to-right ora right-to-left flip to the portion of the content.
 5. The IHS of claim1, wherein to apply the video or image mirroring operation, the programinstructions, upon execution, cause the IHS to determine whether toenforce a video or image mirroring policy based, at least in part, uponcontext.
 6. The IHS of claim 5, wherein the context comprises aclassification of the content.
 7. The IHS of claim 5, wherein thecontext comprises an identity or role of an originator of the content.8. The IHS of claim 5, wherein the context comprises a type of thecommunication session.
 9. The IHS of claim 5, wherein the contextcomprises an identification or proximity of a participant of thecommunication session.
 10. The IHS of claim 5, wherein the contextcomprises an IHS location.
 11. The IHS of claim 5, wherein the contextcomprises an IHS posture.
 12. The IHS of claim 5, wherein the contextcomprises a determination of whether a camera source is front-facing orrear-facing with respect to the IHS.
 13. The IHS of claim 5, wherein thecontext comprises an identification of a communication applicationconfigured to establish the communication session.
 14. The IHS of claim1, wherein the notification is provided by a communication applicationregistered with the platform framework via an Application ProgrammingInterface (API), and wherein application of the video or image mirroringoperation is initiated by an optimizer application registered with theplatform framework via the API.
 15. A memory storage device havingprogram instructions stored thereon that, upon execution by anInformation Handling System (IHS), cause the IHS to: identify a video orimage mirroring policy based on context information provided by at leastone sensor coupled to the IHS; and enforce the video or image mirroringpolicy, via a platform framework, during a communication session. 16.The memory storage device of claim 15, wherein to enforce the video orimage mirroring policy, the program instructions, upon execution, causethe IHS to apply a left-to-right or a right-to-left operation to contentshared during the communication session based on the context.
 17. Thememory storage device of claim 16, wherein the context comprises atleast one of: a classification of the content, an identity or role of anoriginator of the content, a type of the communication session, anidentification of a participant of the communication session, aproximity of the participant to the IHS, an IHS location, an IHSposture, or a determination of whether a camera source is front-facingor rear-facing with respect to the IHS, or an identification of acommunication application configured to establish the communicationsession.
 18. A method, comprising: identifying a video or imagemirroring policy applicable to a communication session, wherein thevideo or imaging mirroring policy contains one or more rules fordeciding whether to change the orientation of a given component or layerof a video or image during a communication session; and enforcing thevideo or image mirroring policy with respect to content shared duringthe communication session, wherein enforcing the video or imagemirroring policy comprises flipping pixels in only a portion of thecontent in the given component or layer of the video or image around ahorizontal or vertical center axis.
 19. The method of claim 18, whereinenforcing the video or image mirroring policy comprises selectingbetween a left-to-right or a right-to-left operation to the portion ofthe content based on context.
 20. The method of claim 19, wherein thecontext comprises at least one of: a classification of the content, anidentity or role of an originator of the content, a type of thecommunication session, an identification of a participant of thecommunication session, a proximity of the participant, a location, aposture, a determination of whether a camera source is front-facing orrear-facing, or an identification of a communication applicationconfigured to establish the communication session.